[[1] Shuster M D, S. D. O H. Three-axis attitude determination from vector observations. Journal of Guidance Control & Dynamics, 1981, 4(1). 10.2514/3.19717]Search in Google Scholar
[[2] Han, K., Wang, H., & Jin, Z. H. (2010). Magnetometer-only linear attitude estimation for bias momentum pico-satellite. Journal of Zhejiang University-SCIENCE A, 11(6), 455-464.10.1631/jzus.A0900725]Open DOISearch in Google Scholar
[[3] Van, d. H. J. C. (2009). Progress in satellite attitude determination and control. Transactions of the Japan Society for Aeronautical & Space Sciences Space Technology Japan, 57(666), 191-198.]Search in Google Scholar
[[4] Çelik, O., & Hajiyev, C. (2013). A comparison of attitude determination methods for small satellites. International Conference on Recent Advances in Space Technologies (pp.261-264). IEEE.]Search in Google Scholar
[[5] Song, L. L., Zhang, T., Liang, B., & Yang, J. (2010). Attitude determination method based on star sensor. Journal of System Simulation.]Search in Google Scholar
[[6] Marina, H. G. D., Pereda, F. J., Giron-Sierra, J. M., & Espinosa, F. (2016). UAV attitude estimation using unscented Kalman filter and triad. IEEE Transactions on Industrial Electronics, 59(11), 4465-4474.10.1109/TIE.2011.2163913]Search in Google Scholar
[[7] Li, Y. and Yuan, J. (2005). Attitude determination using GPS vector observations, GNSS World of China 33(3): 51-56.]Search in Google Scholar
[[8] Junior, F. G., & Tosin, M. C. (2007). The attitude determination problem from two reference vectors - a description of the triad algorithm and its attitude covariance matrix. Semina : Ciências Exatas e Tecnológicas, 28(1).]Search in Google Scholar
[[9] Ryzhkov, L. M., Ozhoh, M. V., & Prokopovych, O. V. (2014). Analysis of attitude determination algorithm TRIAD errors. IEEE, International Conference on Methods and Systems of Navigation and Motion Control (pp.176-181). IEEE.10.1109/MSNMC.2014.6979763]Search in Google Scholar
[[10] Hao, C., & Tan, J. B. (2008). Improved triad algorithm for spacecraft attitude determination. Journal of System Simulation.]Search in Google Scholar
[[11] Markley, F. L. (2008). Optimal attitude matrix from two vector measurements. Journal of Guidance Control & Dynamics, 31(3), 765-768.10.2514/1.35597]Search in Google Scholar
[[12] Cordeiro, T. F. K., Costa, J. P. C. L. D., Júnior, R. T. D. S., So, H. C., & Borges, G. A. (2016). Improved kalman-based attitude estimation framework for uavs via an antenna array. Digital Signal Processing, 59, 49-65.10.1016/j.dsp.2016.07.006]Open DOISearch in Google Scholar
[[13] Hadri, A. E., Benziane, L., Seba, A., & Benallegue, A. (2016). Sensors model based data fusion using complementary filters for attitude estimation and stabilization. IEEE International Conference on Robotics and Automation (pp.2978-2983). IEEE.10.1109/ICRA.2016.7487463]Search in Google Scholar
[[14] Vetrella, A. R., Fasano, G., Accardo, D., & Moccia, A. (2016). Differential GNSS and vision-based tracking to improve navigation performance in cooperative multi-uav systems. Sensors, 16(12).10.3390/s16122164519114327999318]Search in Google Scholar
[[15] Wang, Y., Chang-Siu, E., Brown, M., Tomizuka, M., Almajed, M. I., & Alsuwaidan, B. N. (2012). Three Dimensional Attitude Estimation via the Triad Algorithm and a Time- Varying Complementary Filter. ASME 2012, Dynamic Systems and Control Conference Joint with the Jsme 2012, Motion and Vibration Conference (pp.157-165).10.1115/DSCC2012-MOVIC2012-8512]Search in Google Scholar
[[16] Wang, Y. (2015). Attitude control and estimation. Dissertations & Theses - Gradworks.]Search in Google Scholar
[[17] Baritzhack, I. Y., & Harman, R. R. (1997). Optimized triad algorithm for attitude determination. Journal of Guidance Control & Dynamics, 20(1), 208-211.10.2514/2.4025]Search in Google Scholar
